DE3221567A1 - Fluidized bed furnace - Google Patents

Abstract

The safety ski binding according to the invention has an electronic circuit which detects the forces and / or moments acting on the skier's leg by at least one transducer and, when a predetermined threshold value is reached, excites or de-excites an electromagnet whose armature releases the locking of the sole holder. The sole holder is loaded by at least one spring in the direction of its open position and held in its closed position by the locking device. To release the lock, a release part is provided in the locking device and the force of at least one spring is stored, which is a multiple of the force applied by the armature. A simple mechanical structure and easy operation of the safety ski binding are provided by the fact that the sole holder (4) is assigned a locking pedal (5) and that the locking pedal (5) is the starting link of a kinematic chain which comprises a clamping piece (37) , via which, with the closing movement of the sole holder (4), the relaxed spring or springs of the locking device forming the end link of the chain are tensioned.

Description

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The invention relates to a fluidized bed furnace with closed side walls and an inflow base with a vortex box for fluidizing gas and a method for operating such a fluidized bed furnace.
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Fluidized bed furnaces are used in a wide variety of areas of application the treatment of bulk solids. They are operated in such a way that the bulk material is loosened by fluidizing gas and is kept in a certain limbo.

From EP-Al 042 093 (patent application 81 10 41 98) is a Fluidized bed furnace of the type mentioned is known, in which a good mixing of the freshly fed in from above Bulk material particles and their penetration almost to the level of the inflow base is thereby achieved, that the inflow plate in the area below the feed points has a reduced or> r completely absent gas permeability having. The downward movement of the bulk material particles that occurs in such "calm zones" becomes supported by these (calm zones) delimiting, blind-like wall installations. Furthermore, built-in floors be provided with sloping side walls in the calmed zones of the inflow base to prevent the lateral exit to support the bulk particles from the calmed into the vortex zones. - It turned out that the discharge of the bulk material particles, which sink in the calmed zones, into the vortex zones in some applications does not set securely,

It is therefore the object of the invention in a fluidized bed furnace of the aforementioned Ar ^ the circulation of the To improve bulk material particles, in particular their flow into adjacent vortex zones. This is achieved through preferably in pairs, at a distance from each other in the vertebral

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layer furnace extending, of fluidized material underneath and Wall installations that can be flowed over and gas ejectors in the lower part Part of the built-in wall. The advantage of this combination is there in the fact that bulk material particles which are preferably falling within the pairs of walls are ejected by the use of the ejector are loosened in the vicinity of the built-in walls, especially in the vicinity of the inflow base, in such a way that that they flow off into the lateral vertebral zones. So there is a downward movement on one side of the built-in wall and on the opposite side an upward movement of the bulk material particles, while bulk material particles Overcoming the built-in walls by flowing in over or from the side or by means of the ejector gas infiltrate. - Accordingly, it can be with the built-in wall z. B. be brick walls with breakthroughs or openings between the inflow base and the surface of the swirling layer, but also around such wall installations with further openings.

By means of an inflow plate with reduced gas permeability within pairs of walls with a downward-facing Bulk material movement is reduced or completely suppressed, the swirling of the bulk material particles within the wall pairs and thereby supports the downward movement. A simple way of increasing the gas permeability of the inflow base reduce, consists in the use of the already mentioned floor installations with sloping side walls. By a corresponding steepness of the side walls of these internals results in a desired lateral drainage of the bulk material particles into normal swirling zones.

Ejector nozzles with an orientation towards the normal swirling Zones support the lateral discharge of particles from particle sinks; the ejector nozzles can be attached to the Built-in walls themselves are located; particularly simple and we-

However, they are impressive in the form of holes in the side walls ejector nozzles provided for the above-mentioned floor installations. These are particularly effective in preventing weaning the solid particles above the built-in floor and increase in connection with the slope of the side walls the drainage of the bulk material particles.

Through louvre-shaped wall fixtures, as they are for. B. continue were mentioned above, the gas and solids exchange promoted between the two sides of the individual wall fixtures; especially promote inward between the Wall fixtures inclined, roughly horizontally extending blind strips prevent particles from entering the subsidence zones.

In a preferred method of operating a fluidized bed furnace of the type described above, quantities of ejector gas are fed into the fluidized bed furnace in such a controlled manner, that the correspondingly adjusting bulk material circulation does justice to the respective process requirements will. The advantage of this measure is that the loosening condition is achieved with an increase or decrease in the amount of ejector gas the bulk material particles and their drainage from the lowering zone varies widely and can also be operated intermittently.

Further advantages and refinements of the invention emerge from the description of a in the accompanying drawing illustrated embodiment. In the drawing show:

1 shows a fluidized bed furnace in vertical section, FIG. 2 shows an enlarged illustration of a detail of a fluidized bed furnace in vertical section.

A fluidized bed furnace has closed side walls 1 and a gas-permeable inflow base 2 as the ceiling of a wind box 3, into which fluidizing gas is fed through a gas connection nozzle 4. Above the inflow plate 2
extend spaced, gas-permeable wall fixtures 5. In the lower part of the wall fixtures, gas ejectors 6 are provided on these or on the inflow base 2, from which ejector gas flows out in predeterminable directions shown by arrows in the drawing.
This results in density differences in adjacent bulk material areas, which causes a loosening in the area of greater densities due to particle runoff.

The built-in walls 5 are preferably in pairs, as in FIG

Center of Fig. 1, provided, but also in the vicinity of the side walls 1 of the fluidized bed furnace, and the ejectors 6 are arranged so that they cause a bulk flow to the outside of the wall pairs. This creates between wall fixtures arranged in pairs or

Wall fixtures and adjacent side walls of the fluidized bed furnace downward particle flows and corresponding upward particle flows between different pairs of walls, as shown by flow arrows in Fig. 1; in the upper part of the wall Built-in bulk particles flow through and / or over them, so that the circulation is automatic. in Gang remains, which is supported by the fact that bulk material particles in a fluidized bed furnace through the Fluidization behave similarly to a liquid.

A bulk material feeder 7 above the zones with downwards Directed particle flow ensures that the freshly fed in particles sink to about the level of the inflow plate and thus support the good avoidance

of such particles. - With these particles it can

are also cyclone dust, which is produced when fluidizing material and fluidizing gas are separated. - A bulk material overflow 8 ensures the disposal of the fluidized bed furnace of bulk material.
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In Fig. 2 it can be seen that the upper limit of the fluidized bed 9 is slightly trough-shaped above the zones of the lowering of the bulk material. Wall fixtures consist of blind slats 10, which are held in position by struts 11. Between a pair of built-in walls with inside bevelled louvre blades, a floor installation part 12 is arranged in prismatic form on the inflow base 2; this has gas ejectors 6 in the sloping side walls aligned in the direction of the zones with upward particle flow (see flow arrows) are. Such built-in floor parts can also be pipes stacked or arranged in the form of a prism which preferably flow ejector and / or fluidizing gas and, if necessary, can flow out through lateral passages. The rest limit the bulk material particle bed that is not exposed to the flow is represented by 14. Depending on the size and number of gas ejectors as well as the controllable amount of ejector gas escaping through it, the bulk solids circulate in their Strength varies. There are special dimensions in each case from the application and can easily be determine.

Openings 15 for gas or particle exchange can be in Form of holes, slots and similar openings in the built-in wall.

Channels 16 through which a heat transfer fluid flows to the Wall fixtures 5 can ensure their cooling or heating.

Claims (6)

BERGWERKSVERBAND GMBH TESTING COMPANIES OF BERGBAU-FORSCHUNG GMBH Essen, 03.06.1982 / Be fluidized bed furnace patent claims 1. Fluidized bed furnace with closed side walls (1) and an inflow base (2) with wind box (3) for fluidizing gas, characterized by wall fixtures (5) and gas ejectors (6) in the lower part which extend at a distance from one another and can be flowed over and under by fluidized material Part of the built-in wall. 2. Fluidized bed furnace according to claim 1, characterized by an inflow base (2) with reduced gas permeability within pairs of walls (5, 5) or (5, 1). 3. Fluidized bed furnace according to claim 1 or 2, characterized by floor fittings (12) within the wall pairs (5, 5) or (5, 1) with sloping side walls (13). 4. Fluidized bed furnace according to Claim 3, characterized by gas ejectors (6) in the side walls 13. 5. Fluidized bed furnace according to one or more of claims 1 to 4, characterized by louvre-shaped wall fixtures (5, 10, 11). 6. A method for operating a fluidized bed furnace according to claim 1, characterized in that ejector gas is fed into the fluidized bed furnace in controllable quantities.